UA81937C2 - Method for heating premises and system for its implementation - Google Patents

Abstract

Method and system for heating premises relate to heat engineering. Group of premises of different consumers one heats from heat and electric networks. One measures temperature of environmental air and at heat entry one sets temperature of heat carrier, that at not operating system of electric heating provides temperature in premises that is higher than that of breakdown, though lower than standart one. Heating system consists of boiler room with heat supply network, heaters installed in premises, connected to that network, and command apparatuses with installed in consumer premises temperature indicators for control of heating premises. Those are connected to dispatcher’s center of heating system, through power input – to electric network, and through power output – to electric heaters. At heat entry common for group of consumers additional command apparatus is installed, with indicator of temperature of environmental air. Those inventions promote control of temperature in premises from control point and by consumer’s will as well. This stimulates payment for services and increases comfort in premises.

Description

Description of the invention

The proposed group of inventions refers to the field of heat engineering and can be used in systems 2 of centralized heating of residential and communal facilities.

From the description of the work according to the international application UMO 97/02455 A1, M.cl. E24011/00, publ. 23.01.97 a known heating method, according to which a group of premises of different consumers is heated from a centralized heating system, maintaining a set temperature separately for the premises of each consumer by changing the amount of energy entering the premises of the consumer so that, if necessary, the temperature in the premises decreases, but is not lower than 70 emergency, while the necessary amount of energy is stored in the heat accumulator, taking into account the credit for payment of heating. This method is implemented by a heating system, which is the closest technical solution adopted as a prototype, which consists of a boiler room with a heat supply network, heaters connected to this network through a heat accumulator and a prepayment unit installed at the consumer to control the heaters, while the control output of the prepaid unit 72 is connected to the input of the heat accumulator control unit, which, in addition, is connected by a communication channel to the dispatch center.

This method of heating and such a system for its implementation create the possibility of limiting the supply of heat to consumers who do not pay for heating services, as well as optimizing the heat load on the power grid due to the redistribution of this load in the chavsa. 20 The disadvantage of this method is the need to accumulate hot water energy for each consumer in containers that must have significant dimensions. This leads to the need to place heat-accumulating equipment in separate rooms, as well as to heat losses during storage. The disadvantage of the heating system designed for the implementation of this method is the presence of hot water accumulators in it for each consumer, which makes the heating system cumbersome and difficult to implement and maintain. Disadvantages include the need to enter prepayment information into the prepayment unit directly from the consumer by programming it with a mobile access device, as well as significant losses of primary fuel energy in the process of energy generation and its transportation to the consumer.

The closest in terms of technical essence and the number of matching features is the method of space heating chosen as a prototype, known from the description of the operation of the device according to (patent of Ukraine Mo72640, M.kl. E2403/00, и-30 opul. 15.03.05.1 a group of premises of different consumers are heated by two heating systems, to which heaters are fed energy from the heating and electrical networks, maintaining the set temperature separately for the premises of each consumer so that, if necessary, the temperature in the Me premises decreases, but does not fall below the emergency level, while thermal energy are produced in cogeneration mode - pr together with electricity, regulation of the amount of energy is carried out by disconnecting at least 39 parts of the heaters from the power grid by a team from the dispatch center, and the number of disconnected heaters and the length of time the heaters stay in the disconnected state are set taking into account the set temperature in the premises.

This method is implemented by a heating system, which is the closest, adopted as a prototype, technical solution, which consists of a boiler room with a heat supply network, heaters installed in the premises, connected to this network, as well as control devices with temperature sensors for 70 room heating control, installed in the premises of consumers, and connected through the control channel to the control center of the heating system, through the power input - to the power grid, and through the power output - to the electric heaters, while the boiler room is equipped with equipment for converting thermal energy into electrical energy, and its generator is connected to electric heaters through the power grid.

This method makes it possible to ensure a decrease in the temperature in the consumer's premises in case of untimely payment of 45 heat supply services. However, it is difficult to implement. The fact is that in case of non-payment of the co-heating service, electric heaters can be turned off easily and without problems. But the periodic switching off - switching on - of water heaters will lead to a dynamic imbalance of the centralized heating network and to unpredictable changes in the surface temperature of water heaters located in the premises of neighboring consumers. If we limit ourselves to turning off only electric heaters, then the effectiveness of such a 20-second cut-off will be questionable, because in order to ensure a temperature in the room when the heaters are turned off, not lower than the emergency temperature, the electric heaters must heat the room by no more than 10...159C, since at a temperature of minus 18...222C (calculated heating temperature), the temperature in it should not be lower than plus 5...1090. That is, when heating by this method, the water heating system must provide heating of the room by 25...342C, and disconnection of only the electric heating system will be noticeable only when the outside air temperature drops to a level below minus 5...1520. And on such days in the heating

GF) in the season only from 15 to 295, respectively. Another disadvantage of this method is the need for cogeneration production of electricity and heat, which limits its use in small heat networks, for example, in district centers. When connecting electric heaters to the general power grid, this is not necessary, since during the night shift it is possible to accumulate heat at the expense of consumption of non-liquid electricity from other thermal power plants | see an article

O.L. Svetelika, A.G. Batalova, A.I. Zamulko, A.V. Prakhovnyk and V.F. Nakhodov "Ways of ensuring the balance of production and consumption of electric energy and capacity of UES of Ukraine", P.-285-2 94 in the collection "The state and future of energy of Ukraine", Kyiv, "GRIFFE", 20051. 65 The heating system, adopted as a prototype, has the above-mentioned disadvantages, and, in addition, its use requires periodic access to the premises of the consumer by employees of the heat supply organization for maintenance of hydraulic switches, as well as to check the functionality of their protection against unauthorized entry. Gaining such access can be very difficult, especially if an unauthorized intrusion has occurred.

The purpose of creating the proposed group of inventions is to develop a method of heating premises, as well as a relatively cheap and easy-to-maintain and control system for its implementation, suitable for modernizing the heating of the existing housing stock, which would ensure the stimulation of heating bills by managing the temperature regimes of the premises separately for each consumer from the dispatch center of the centralized heating system in the entire temperature range of the heating season. An additional goal is 7/0 simple control over the use of the system, which would not be restricted by the current legal ban on access to the consumer's premises, stabilization of the operation of the central heating system of the house as a whole and, in addition, the stability of the temperature in the heated premises.

The problem is solved by the fact that in a known method of heating premises, which consists in the fact that a group of premises of different consumers is heated by two heating systems, to which heaters are fed energy from the heating and electrical networks, maintaining the set temperature separately for the premises of each consumer so that so that, if necessary, the temperature in the room decreases, but does not fall below the emergency temperature, during the heating process, the temperature of the outside air is measured, and, taking into account it, as well as the thermal resistance of the heated group of rooms, the temperature of the coolant is set at the heating input, which ensures, with the system not working of electric heating, the temperature in the premises is at a level higher than the emergency value, 2°C but lower than the value of the standard heating temperature.

A variant of this method is possible, when electricity is consumed periodically with the accumulation of heat and its subsequent use to maintain the temperature in the premises, while the temperature of the coolant is set to the lowest after the accumulation process is completed and raised to the highest value before the start of this process. high school

Regarding the system for implementing the method, the problem is solved by the fact that there is a known system for implementing the heating method, which consists of a boiler room with a heat supply network, heaters installed in the premises, connected to this network, as well as control devices with temperature sensors installed in the premises of consumers to control the heating of rooms connected through the control channel to the dispatching center of the heating system, through the power input - to the power grid, and through the power output - to the electric heaters, an additional command device with an outdoor temperature sensor is installed on the thermal input common to the group of consumers air placed outside the premises of consumers. co

In the version of this system, the temperature sensors of the electrical control devices installed in b rooms are included in the electrical network between the power output of the control device and the electronic heater and are designed as thermostats. h-

Thermoregulators can be made with the possibility of controlling the activation setting through a control unit.

As an implementation option, a heating system is possible, in which the control unit installed on the thermal input is designed as a mixer of coolants with different temperatures.

The control device installed on the thermal input can be made with the possibility of connection through the channel "

Control with the dispatch center of the heating system. - с Between the set of essential features of the method and the technical result achieved, there is a cause-and-effect relationship due to the implementation of regulation according to various parameters, when the basic flow of energy for heating from the heat network depends on the external temperature and the degree of discharge of the heat accumulator, and the auxiliary the flow of energy from the grid depends on the preferences of the consumer and his ability to pay.

Regulating the temperature of the coolant on the general heat input, taking into account the external temperature oo and the thermal resistance of the premises, provides the same basic temperature in the premises of all consumers, independent of the temperature of the outside air, which, when the electric heaters are turned off, is higher than the emergency temperature and lower than the comfortable temperature. From this temperature, heating of the room with electric heaters begins, up to a level determined by the consumer's needs and ability to pay.

A decrease in the temperature of the heat carrier at the end of charging electric heat storage heaters and its gradual increase before the start of the next charge equalizes the temperature in the premises, which at a constant temperature of the heat carrier will decrease as the heat accumulators discharge.

There is a cause-and-effect relationship between the set of essential features of the heating system and the technical result that is achieved, due to the placement of the hydraulic control unit with the external air temperature sensor on the common thermal input. This makes it possible to ensure the same heating conditions with the centralized heat supply system for the premises of all consumers. These conditions are independent of temperature

HF) of outside air and are maintained throughout the heating season. In addition, circulation modes

Ф of the coolant in the system remains unchanged, which stabilizes its operation.

Placement of hydraulic, and if necessary, electrical control devices outside the boundaries of consumers' premises, provides the possibility of control and maintenance by heat supply organizations without restrictions on the part of consumers.

If at the same time room temperature sensors are designed as thermostats and included in the power network between the control unit and the heater, the electrical part of the system is simplified and therefore cheaper.

The possibility of controlling the activation setting through the command device expands the functionality of such a heating system due to the possibility of maintaining different room temperatures at different hours of the day.

If the control device is made in the form of a mixer of hot water coming from the heating network and cooled water circulating in the heating system, then this stabilizes the operation of the water heating system, since the circulation of the coolant in it is maintained in a constant mode.

The ability of the command device installed on the common thermal input to change the temperature of the heat carrier according to the commands of the dispatch center not only depending on the temperature of the outside air, but also on the time of discharge of the thermal accumulator of the electric heater, provides compensation for the cooling of the thermal accumulators and makes it possible to maintain a stable temperature in the room at a lower temperature heat capacity, and accordingly, smaller capital investments.

Analysis of domestic and foreign scientific and technical and patent literature did not reveal technical solutions, 7/0 that have similar characteristics. This allows to consider the inventions included in the declared group as satisfying the "novelty" criterion.

The proposed technical solutions also do not follow clearly from the known state of the art for specialists. This allows to consider the inventions included in the declared group as meeting the "inventive level" criterion.

The set of essential features characterizing the essence of the claimed inventions can be used multiple times in residential and communal heating systems to achieve the technical result of increasing the energy efficiency of centralized heating and reducing the cost of its modernization process. This allows us to conclude that the claimed inventions meet the "industrial suitability" criterion.

The claimed method, as well as systems for its implementation, are explained by drawings.

Fig. 1 schematically shows the heating system of the premises of a group of consumers located in the same building, Fig. 2 shows the graphs of internal room temperatures when heated by such a system, Fig. 3 shows the temperature graphs when heated by a system with energy-accumulating electric heaters and periodic changes in the temperature of the medium depending on the discharge of heat accumulators. with

The heating system of the premises of the group of consumers (Fig. 1) includes a boiler room 1, to which water heaters 3 are connected through the heating network 2, located in the premises 4a, 46, 4c of different consumers located in one (o) building. In addition, electric heaters 5 are installed in these premises, which are connected to the electrical network 7 through control devices 6. Temperature sensors 8 are installed in consumer premises and connected to control devices 6. At the same time, depending on the design of the control device and the sensor, the sensor b can be directly connected to the control input 9 of the command device, or be installed between the power output 10 of the command device b and the electric heater 5. In the latter case, the temperature sensor 8 must be made in the form of a thermostat. If the temperature sensor (thermostat) 8 has an input 11 for controlling the activation setting, then it is connected to the control output 12 of the control unit 6. The control inputs 13 of the control units 6 are connected to the control center 15 through the control channel 14. h-

Between the heat network 2 and the water heaters of all consumers of the house, a control unit 17 is installed on the heat input 16, the control input 18 of which is connected to the outdoor air sensor 19, and the control input 20 is connected to the control center 15 through the control channel 21.

The temperature in the premises of all consumers of the house (Fig. 2), regardless of the value of the outside air temperature, when electric heaters are not working due to energy from the heating network "

Maintained at one level (line 22). At the same time, the room is heated by electric heaters by several degrees (line 23). Since temperature is a scalar value, the total temperature of the room is the sum of the temperatures provided by the consumption of both energy from the heating network and energy from the electrical network (line 24).

If the consumption of electricity is periodic, and the electric heaters are energy-accumulating, then the temperature of reheating is not a constant value (line 25, Fig. 3). At the same time, to ensure the stability of the temperature in the room (line 24), the temperature maintained due to energy consumption from the heating network should also not be a constant value (line 26). The method of heating the premises consists in the fact that a group of premises located in one building with 4 different consumers is heated from a centralized heating system, consisting of a boiler room 1, a heating network 2 and a dispatch center 15, maintaining the set temperature separately for the premises 4 of each consumer as , so that when necessary, the temperature in the premises decreases, but is not lower than the emergency temperature, at which either defrosting of pipes in industrial premises or significant hypothermia of people in residential premises takes place.

At the same time, the energy from the heating circuit 2 is supplied to the water heaters C through the control device 17, installed on the common heat input 16. The regulation of the amount of energy supplied to the room 4 from the heat network 2 is carried out by the control device 17 according to the signals of the sensor 19 of the outside air temperature, which are received on

HF) input 18 of the command device 17, and taking into account the thermal resistance of the premises 4. If necessary (a sudden change in the weather, strong wind at temperatures close to 02C), the adjustment of the mode of operation of the command device can be carried out according to signals from the dispatch center 15, which is fed to the input 20 of the command device 17 on channel 21 because of management.

If any of the consumers do not pay for the room heating services, a shutdown signal is sent from the control center 15 through the control channel 14 to the input 13 of the control unit b and the electric heaters 5 are disconnected from the power grid 7. The temperature in the room 4 decreases to the specified minimum, (line 22,

Fig. 2) which, in order to prevent noticeable heat flows from the premises of other consumers, should not be lower than 65 8..109С, and to prevent defrosting of the heating system - not lower than 5 2С. At this level, the room temperature is maintained during the heating season at any outside air temperature due to energy consumption from the heating network with regulation of heat consumption in the order described above.

After the consumer pays for the heating service, a signal is sent to the input 13 of the control unit 6 through the control channel 14 from the dispatch center 15 to connect the electric heaters 5 located in the consumer's premises to the power grid 7. At the same time, due to the consumption of electricity by heaters 5, at the request of the consumer, the premises are heated up by several degrees (line 23, Fig. 2). As a result, the room warms up to the set temperature (line 24, Fig. 2), the level of which is set by the consumer by means of control devices 6, if the room temperature sensor is connected to its input 9 (room 4c), or by means of temperature sensor control 8, if it is installed , as a thermostat (rooms 4a and 46). 7/0 At the same time, in the rooms 4b, the control unit 6 performs the function of connecting the heaters 5 to the power grid according to the time, the fact of payment, and the deviation of the temperature in the room from the set value. In rooms 4a and 46, the function of connecting the heaters 5 to the power grid according to the deviation of the temperature in the room from the set value is performed by the thermostat 8, closing the electric circuit from the output 10 of the control device b to the heater 5, and the function of connecting the heaters to the power network according to the time and the fact of payment is performed by the control device 6. In the room /5, the control unit b also performs the function of controlling the thermostat 8, which is achieved by sending a control signal from the output 12 of the control unit 6 to the input 11 of the sensor - the thermostat 8. This makes it possible, by lowering the operating temperature, to limit the consumption of electricity to maintain the temperature in the room during the hours when there are no people in it.

The control unit 17 can connect the heaters from all consumers to the heat network 2 periodically, while the ratio of the time of heat consumption to the total length of time will be a function of the difference between the minimum temperature in the premises and the temperature of the outside air. However, more stable operation of the water heating system is achieved when the control unit 17 is executed as an adjustable mixer of water supplied from the heating network and water circulating in the heating system. In this case, the water heating system works all the time in the calculated energy carrier circulation mode, which prevents disruptions in the circulation mode in individual sections of the system.

If the electric heaters 5 are heat-accumulating, then the control devices b connect them to (8) the power grid only at night, during a load failure in the power grid 7. At the same time, the consumed heat is mainly spent on heating the heat-accumulating material of the heater b. But part of the heat, getting into the room 4, leads to an increase in the temperature in it at the end of charging the heat-accumulating electric heaters 5 (line 25, Fig. 6). At the same time, in order to maintain a constant temperature in the room, it is necessary to reduce the heating of the room due to heat consumption from the heating network (line 24, Fig. 3). As the heat accumulators are discharged, the heating temperature (line 25) will decrease, and therefore, to stabilize the temperature in the room, it is necessary to increase the heating of the room due to heat consumption from the heating network (line 24). This regulation of heat consumption from the heating network will ensure uniformity of temperature in the room when using heat-accumulating electric heating. co

Thus, the claimed group of inventions, which includes a method of heating rooms and a heating system for its implementation, allows you to control the temperature regime in the rooms, lowering the temperature in them, on command from the dispatch center or at the request of the consumer, during the entire heating season, regardless of climatic conditions. This will ensure the creation of a mechanism for stimulating payments for heating services without expensive reconstruction of centralized heating systems in most modern buildings. In addition, it will enable consumers to regulate the temperature in their premises heated by central heating, at their own discretion and according to their own financial capabilities, without disturbing the operating modes of the central heating system. At the same time, the dependence of the consumer's expenses on electric heating on his implementation of energy-saving measures will stimulate energy saving

In the household sphere. co

Claims (7)

- The formula of the invention 1. A method of heating premises, in which a group of premises of different consumers is heated by two heating systems, to the heaters of which energy is supplied from the heating and electrical networks, maintaining the set -h temperature separately for the premises of each consumer, so that the temperature in the premises decreases if necessary, but was not lower than the emergency temperature, which is distinguished by the fact that during the heating process, the temperature of the outside air is measured, taking into account which temperature of the heat carrier is set at the heating inlet, which, when the electric heating system is not working, provides a temperature in the premises that is higher than the emergency temperature, but lower than standard heating temperature. GF) 2. The method according to claim 1, which differs in that electricity is consumed periodically with the accumulation of heat and its subsequent use to maintain the temperature in the premises, while the temperature of the coolant dk is set to the lowest after the accumulation process is completed and raised to the highest value before the start of this process. 3. A heating system consisting of a boiler room with a heat supply network, heaters installed in the premises connected to this network, as well as control devices with temperature sensors installed in the consumer premises to control the heating of the premises, connected through a control channel to the dispatching center of the heating system, through the power input - with the power grid, and through the power output - with 65 electric heaters, which differs in that an additional control device with an outdoor air temperature sensor, located outside the consumer's premises, is installed on the thermal input common to a group of consumers. 4. The system according to item 3, which differs in that the temperature sensors of the electrical control devices installed in the premises are included in the electrical network between the power output of the control device and the electronic heater and are designed as thermostats. 5. The system according to claim 4, which is distinguished by the fact that the thermostats are made with the possibility of controlling the activation setting through the control unit. 6. The system according to claim 3, which is characterized by the fact that the control device installed on the thermal input is designed as a mixer of coolants with different temperatures. 70 7. The system according to claim 3, which differs in that the control unit installed on the thermal input is made with the possibility of connection through the control channel with the dispatching center of the heating system. s 7 o che (ze) (22) "-- Zo so - and? co - (Se) o what co 60 b5